Icarus wrote:Instead of buying masks should we consider buying humidifiers? The science behind it seems pretty solid. Most respiratory diseases spread via tiny droplets when people sneeze or cough. This is the primary method in which coronavirus is passed on to others (touching the virus and then touching our mouths is secondary). The reason more people get sick during the winter is because of the dry air. When the air is more humid during the summer months it becomes heavier and those droplets tend to fall to the ground. With dry air, the droplets are more likely to be inhaled by others.
https://www.livescience.com/27533-flu-t ... nHDbgdrvUk
I have the sense that the people who wrote that article may not have got that quite right. That sentence "When the air is more humid during the summer months it becomes heavier and those droplets tend to fall to the ground" is both confused and confusing.
From the physical point of view, it's more like this:
1. In any given air conditions, a large drop of fluid released into still air will, other factors being kept constant, fall faster towards the ground than a small one.
2. Why?
(a) The maximum speed of a freely falling droplet will be the speed at which the upwards frictional force exerted on the droplet by the air through which the droplet moves is equal to the downwards force exerted on the droplet by earth's gravitational field (the 'weight') of the drop. (Hence the total force is zero, and the drop neither speeds up nor slows down: Newton's first law of motion, applied to motion in a straight line.)
(b) If you double the diameter of a drop, its volume (hence its mass, hence its weight) will increase by 2^3 = 8, whereas its surface area will only increase by 2^2=4. So the weight increases twice as fast as the friction, and the drop will reach a greater maximum falling speed.
3. If the air is already carrying all the water molecules it can manage (100% relative humidity, 'saturation'), any molecules of water that escape from the surface of the drop will be replaced by other water molecules entering the drop from the surrounding air. So a big drop stays big, and falls fast.
4. But if the air is carrying few water molecules, (low relative humidity), molecules of water that escape from the surface of the drop will NOT be replaced by other water molecules entering the drop from the surrounding air. So a big drop stays big, and falls more slowly. If it gets small enough, its falling speed will be so small that it just gets moved around by air currents, and is unlikely to reach the ground in any reasonable time.
5. What's this got to do with infection? Well, if I sneeze out big drops of water loaded with virus and relative humidity is high, they will not shrink, and will hit the ground quite soon, with less chance of passing infection to someone. But if humidity is low, drops that start off large may shrink quickly enough so that they become small and hang about in the air long enough for someone else to breath them in, together with the viruses they carry.
So ... low humidity raises the chance that the virus will be transmitted by droplets.
For a big dose of relevant science, see:
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6364647/